14.3 Transition state theory and activated complex
4 min read•july 30, 2024
theory explains how reactions happen through high-energy activated complexes. It's all about molecules overcoming energy barriers to transform into products. This theory helps us understand why some reactions are fast and others are slow.
The and temperature are key players in determining reaction rates. By manipulating these factors, we can control how quickly reactions occur. This knowledge is crucial for optimizing chemical processes in various industries.
Transition State Theory
Key Concepts and Assumptions
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- Transition state theory explains the rates of elementary reactions by assuming that reactants must pass through a high-energy transition state or to form products
- The activated complex is a transient, unstable species formed when reactants collide with sufficient energy and proper orientation, representing the highest energy point along the
- The activated complex is in equilibrium with the reactants, and its concentration determines the rate of product formation
- The difference in energy between the reactants and the activated complex is the activation energy (), the minimum energy required for a reaction to occur
Factors Affecting Reaction Rate
- The rate of a reaction depends on the concentration of the activated complex, which in turn depends on the activation energy and temperature
- Higher concentrations of the activated complex lead to faster reaction rates, as more reactant molecules have sufficient energy to overcome the activation energy barrier
- Temperature increases the average kinetic energy of molecules, allowing a greater proportion of reactants to form the activated complex and proceed to products
- Catalysts lower the activation energy by providing an alternative , increasing the concentration of the activated complex and the reaction rate
Activation Energy and Rate
Relationship between Activation Energy and Reaction Rate
- The activation energy () is the energy barrier that reactants must overcome to form the activated complex and proceed to products
- A higher activation energy results in a slower reaction rate because fewer reactant molecules have sufficient energy to form the activated complex
- Lowering the activation energy, through the use of catalysts or by increasing temperature, increases the reaction rate by allowing more reactant molecules to form the activated complex
Maxwell-Boltzmann Distribution and Reaction Rates
- The Maxwell-Boltzmann distribution describes the distribution of molecular energies in a system and helps explain why increasing temperature leads to a greater proportion of molecules with energy equal to or greater than the activation energy
- At higher temperatures, the Maxwell-Boltzmann distribution shifts to the right, with a greater area under the curve above the activation energy, indicating a larger fraction of molecules with sufficient energy to react
- Catalysts shift the Maxwell-Boltzmann distribution by lowering the activation energy, allowing a greater proportion of molecules to have the required energy to form the activated complex at a given temperature
Arrhenius Equation Applications
Components of the Arrhenius Equation
- The , , relates the rate constant () to the activation energy (), pre-exponential factor (), gas constant (), and absolute temperature ()
- The pre-exponential factor () represents the frequency of collisions between reactants and the probability of those collisions having the proper orientation for reaction
- The exponential term, , represents the fraction of collisions with sufficient energy to overcome the activation energy barrier
Calculating Rate Constants and Activation Energies
- The Arrhenius equation can be used to calculate the rate constant () at a given temperature if the activation energy and pre-exponential factor are known
- By plotting vs. , the activation energy can be determined from the slope () of the resulting straight line, while the pre-exponential factor () can be determined from the y-intercept
- The Arrhenius equation allows for the prediction of rate constants at different temperatures, enabling the optimization of reaction conditions (temperature, catalyst choice) for desired outcomes
Collision and Orientation in Kinetics
Effective Collisions and Reaction Rates
- For a reaction to occur, reactant molecules must collide with sufficient energy (equal to or greater than the activation energy) and proper orientation
- The collision theory states that the rate of a reaction is proportional to the frequency of effective collisions between reactant molecules
- Effective collisions are those with sufficient energy and proper orientation to break existing bonds and form new bonds, leading to the formation of products
- Increasing the concentration of reactants leads to a higher frequency of collisions and, consequently, a faster reaction rate, as described by the rate law
Molecular Orientation and Steric Factors
- Molecular orientation is crucial because reactants must collide with the proper spatial arrangement for the necessary bonds to break and form, not all collisions with sufficient energy lead to reaction due to improper orientation
- Steric factors, such as the size and shape of reactant molecules, can affect the probability of collisions with proper orientation and impact the pre-exponential factor () in the Arrhenius equation
- Molecules with complex structures or bulky substituents may have a lower probability of effective collisions due to steric hindrance, resulting in a smaller pre-exponential factor and slower reaction rates
- Orientation effects can be particularly important in reactions involving asymmetric molecules or those with specific functional groups that must interact for the reaction to proceed (lock-and-key model in enzyme )
Key Terms to Review (18)
Activated complex: An activated complex, also known as a transition state, is a temporary arrangement of atoms that occurs during a chemical reaction when reactants are transformed into products. This state represents the highest energy point along the reaction pathway and is crucial for understanding how reactions occur and why they have certain rates. The activated complex is essential in transition state theory, which describes how molecules overcome energy barriers to react and form products.
Activation Energy: Activation energy is the minimum energy required for a chemical reaction to occur. It serves as a barrier that reactants must overcome to transform into products, linking molecular interactions to the dynamics of reaction mechanisms, transition states, and reaction rates.
Arrhenius Equation: The Arrhenius Equation is a mathematical formula that expresses the relationship between the rate constant of a chemical reaction and the temperature, while also incorporating the activation energy. This equation illustrates how reaction rates are affected by temperature changes, highlighting that as temperature increases, the rate of reaction typically increases due to more molecules having sufficient energy to overcome the activation barrier. Understanding this equation is crucial for analyzing reaction mechanisms, the formation of activated complexes, and rate laws in chemical kinetics.
Catalysis: Catalysis is the process by which the rate of a chemical reaction is increased by the presence of a substance called a catalyst, which itself remains unchanged after the reaction. This process plays a critical role in facilitating reactions, allowing them to occur more efficiently by lowering the activation energy required. Catalysts can affect the reaction mechanism by providing alternative pathways for reactions to take place, leading to the formation of intermediate species and influencing the overall reaction kinetics.
Endothermic reaction: An endothermic reaction is a chemical process that absorbs heat from its surroundings, resulting in a decrease in temperature of the immediate environment. This type of reaction requires energy input, typically in the form of heat, to proceed. The absorbed energy helps to break bonds in the reactants, leading to the formation of products that possess higher energy than the starting materials.
Enthalpy of Activation: The enthalpy of activation is the energy barrier that must be overcome for a chemical reaction to proceed. This concept is critical in understanding how the energy landscape influences reaction rates, connecting the notion of activation energy to the formation of an activated complex during the transition state of a reaction.
Exothermic reaction: An exothermic reaction is a chemical reaction that releases energy in the form of heat or light to its surroundings. This release of energy often leads to an increase in temperature of the surrounding environment. Exothermic reactions are characterized by the breaking of bonds in reactants and the formation of bonds in products that release more energy than is consumed, which can be explained through concepts like transition states and activated complexes.
Eyring Equation: The Eyring equation is a fundamental formula in chemical kinetics that relates the rate of a chemical reaction to the temperature and activation energy, providing a theoretical framework for understanding how reactions occur. This equation stems from transition state theory, which describes the activated complex formed during a reaction as the system passes through a high-energy transition state before forming products. It emphasizes the importance of temperature and the energy barrier that must be overcome for a reaction to proceed.
Henry Eyring: Henry Eyring was a prominent chemist known for his significant contributions to the development of transition state theory, which describes the formation of an activated complex during chemical reactions. His work helped bridge the gap between thermodynamics and chemical kinetics, providing a deeper understanding of how reactions proceed and the factors that influence their rates. Eyring's theories have had a lasting impact on physical chemistry and have paved the way for advancements in various scientific fields.
High-energy state: A high-energy state refers to a condition in which a molecular system possesses energy levels significantly above its ground state. In the context of chemical reactions, this term is crucial because molecules in a high-energy state are often involved in transition states or activated complexes, representing a temporary arrangement of atoms that occurs during the transformation of reactants to products. Understanding high-energy states helps in analyzing reaction pathways and the energy barriers associated with them.
Potential Energy Surface: A potential energy surface (PES) is a multi-dimensional surface that represents the potential energy of a system as a function of the positions of its nuclei. It plays a crucial role in understanding molecular interactions, transitions, and dynamics, as it provides insights into how energy changes with configuration. The shape and features of the PES are fundamental for analyzing phenomena like vibronic transitions, the behavior of activated complexes, and the application of force fields in simulations.
Rate constant expression: The rate constant expression is a mathematical representation that relates the rate of a chemical reaction to the concentrations of the reactants and the rate constant, which is a specific value that indicates how quickly a reaction proceeds. This expression often takes the form of the rate law, where the rate of reaction is proportional to the concentrations of reactants raised to a power that reflects their stoichiometric coefficients in the balanced equation. Understanding this concept is crucial in analyzing how temperature and other conditions influence the likelihood of reactants forming products via the transition state theory.
Reaction coordinate: A reaction coordinate is a conceptual representation of the progress of a chemical reaction, illustrating the energy changes that occur as reactants transform into products. It provides a way to visualize the transition from the starting materials to the final products, often highlighting key energy barriers and intermediates along the path. This concept is crucial for understanding how reactions proceed through various elementary steps and how transition states and activated complexes play a role in determining reaction rates.
Reaction mechanism: A reaction mechanism is the detailed step-by-step sequence of elementary reactions that lead to the overall transformation of reactants into products in a chemical reaction. This concept is crucial as it helps chemists understand how reactions occur, the nature of the transition states involved, and the factors that affect reaction rates and pathways.
Reaction pathway: A reaction pathway is a series of steps that a chemical reaction undergoes from reactants to products, often depicted in terms of energy changes. This pathway includes the transition states and intermediates involved in the process, illustrating how the system evolves as it approaches equilibrium. Understanding the reaction pathway helps in analyzing the kinetics and mechanisms of chemical reactions.
Svante Arrhenius: Svante Arrhenius was a Swedish scientist known for his groundbreaking work in physical chemistry, particularly his contributions to the theory of chemical kinetics and the concept of the activated complex. He introduced the Arrhenius equation, which describes how temperature affects reaction rates and highlights the importance of energy barriers in chemical reactions. His work laid the foundation for understanding how molecules interact during transitions from reactants to products, crucial for grasping concepts like transition state theory.
Transition State: A transition state is a high-energy, unstable arrangement of atoms that occurs during a chemical reaction, representing the point of maximum energy along the reaction pathway. It is essential in understanding how reactions proceed, as it connects the reactants to the products and plays a crucial role in determining reaction rates and mechanisms.
Unstable intermediate: An unstable intermediate is a transient molecular species that forms during a chemical reaction but does not exist for a long time due to its high energy state. These intermediates play a crucial role in the reaction pathway, often acting as a bridge between reactants and products and are characterized by being at a maximum energy point along the potential energy surface. Their fleeting existence can significantly influence reaction rates and mechanisms.